Parallel multisensor optical particle sensors for flowing fluid systems

ABSTRACT

An optical fluid monitoring system for imaging debris and other particles in a flowing fluid. The system can have multiple sensors (camera and viewing port) connected to a single, remotely located, laser and computer. The system can also include multiple lasers, viewing ports and cameras to be located at different locations in a flow, with each sensor being configured to image a different particle size range. The system can simultaneously image fluid flows on different pieces of equipment. Optical sensors can be arranged on parallel flow conduits, with each sensor configured to image a different particle size range.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of application Ser. No.13/920,769 filed on Jun. 18, 2013. application Ser. No. 13/920,769 is anon-provisional of and claims the benefit of U.S. ProvisionalApplication 61/661,387 filed on Jun. 19, 2012 and of U.S. ProvisionalApplication 61/785,541 filed on Mar. 14, 2013. The entire disclosure ofeach of these documents is incorporated herein in its entirety.

BACKGROUND OF THE INVENTION

1. Technical Field

This is related to systems for optically monitoring objects suspended inflowing fluid, and more particularly, to particle monitoring systems formonitoring the presence and size of debris in oil.

2. Related Technology

U.S. Pat. No. 5,572,320 to Reintjes et al. and U.S. Pat. No. 6,049,381disclose in-situ fluid samplers for identifying particles in a flowingfluid with an optical near-field imaging device. In this system, asingle laser illuminator is co-located with a single viewing port and asingle electronic camera, the camera output being analyzed forparticulate content of the fluid with a single computer processor. U.S.Pat. No. 6,049,381 to Reintjes et al. discloses a real time suspendedparticle monitor that uses a pulsed collimated optical source to producea series of images of particles in a flowing fluid. U.S. Pat. No.7,921,739 to Fjerdingstad et al. discloses a real-time opticalmonitoring system having an automatic on line bottle sampling operation.

U.S. Pat. No. 8,056,400 to Reintjes et al. discloses a system forparticle entrained fluid sampling in a high pressure or high flow ratefluid flow system.

Such sampling systems can identify the number, shape, and size ofparticles in fluids. Information about the metal or other particlespresent in lubricating fluid, for example, can provide valuableinformation about wear in the machinery or other system beinglubricated.

BRIEF SUMMARY OF THE INVENTION

An optical fluid monitoring system for imaging particles in at least oneconduit carrying a flowing fluid, includes a plurality of opticalsensors positioned along the at least one conduit, each sensorpositioned to transmit laser optical energy into a transparent viewingwindow in a fluid flow conduit in a direction across the direction offlow, each sensor having an optical imaging system for receiving theoptical energy after it has passed through the fluid flow and forimaging particles in the fluid flow.

In one example, each optical sensor includes a laser. The lasers in eachoptical sensor can have different wavelengths. In some examples, eachoptical sensor includes at least one optical fiber configured totransmit the optical energy of the laser to the transparent viewingwindow. In some examples, the system includes a single laser that isoperatively coupled to all of the optical sensors. In some examples, aplurality of optical fibers transmits the optical energy output of thelaser to the transparent viewing windows.

In some examples, each imaging system includes a camera and a lensdisposed between the camera and a viewing window in the conduit. In someexamples, a plurality of sensors are arranged in series along a singleconduit, wherein an upstream one of the plurality of sensors isconfigured to image a range of larger size particles and a downstreamone of the plurality of sensors is configured to a range of smaller sizeparticles, and for each sensor, the conduit thickness at that sensor issuch that the particles in the size range to be imaged are in theoptical near field of the imaging system, and wherein the upstreamsensor conduit has a conduit thickness that is larger than thedownstream sensor conduit. In some examples, at least one filter ispositioned in the conduit sized to exclude particles larger than apredetermined size from reaching a downstream sensor.

In some examples, the plurality of sensors are arranged on parallelconduits, with a first of the plurality of sensors configured to image arange of larger size particles and a second of the plurality of sensorsconfigured to image range of smaller size particles, and for eachsensor, the conduit thickness at that sensor is such that the particlesin the size range to be imaged are in the optical near field of theimaging system, and wherein the first sensor conduit has a conduitthickness that is larger than the second sensor conduit. The parallelconduits can connect to a main flow passage at a same tap point and at asame return point.

In some examples, the system also includes a single computer processoroperatively connected to receive images from all of the imaging systems,the computer processor having programmed instructions for classifyingparticle shapes and sizes from the images received from the imagingsystem. The computer processor can be located remote from the opticalsensors.

In some examples, each optical sensor includes a computer processoroperatively connected to the imaging system in the optical sensor, witheach of the computer processor having programmed instructions forclassifying particle shapes and sizes from the images received from theimaging system.

In some examples, a single laser is operatively coupled to all of theoptical sensors; and a single computer processor is operativelyconnected to receive images from all of the imaging systems, thecomputer processor having programmed instructions for classifyingparticle shapes and sizes from the images received from the imagingsystem.

In some examples, the optical fluid monitoring system is adapted forimaging particles in at least two different conduits carrying flowingfluids, the system having at least one of the optical sensors positionedalong each of the different conduits to image the particles in the fluidin that conduit. The system can have at least two of the optical sensorspositioned along each of the different conduits to image the particlesin the fluid in that conduit. Each conduit can be part of a differentpiece of equipment.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an optical particle monitoring system for monitoringthe fluid at several different locations.

FIG. 2 illustrates an optical sensor head suitable for use in an opticalparticle monitoring system for fluid.

FIG. 3 shows an optical particle monitoring system for fluids in whichthe laser and computer processor are located remotely from the viewingwindow and conduit.

FIG. 4 shows an optical particle monitoring system for fluids in whichthe laser and computer processor are located close to the viewing windowand conduit.

FIG. 5 illustrates an optical particle monitoring system with multiplesensor heads.

FIGS. 6A and 6B illustrate options for selecting viewing cellthicknesses to monitor different particle size ranges.

FIG. 7 illustrates an optical particle monitoring system for fluids inwhich the individual sensor heads/viewing cells are connected separatelyto the main flow.

FIG. 8 illustrates an optical particle monitoring system for fluids inwhich the individual sensor heads/viewing cells are connected inparallel to the main flow.

FIG. 9 illustrates an optical particle monitoring system for fluids inwhich a single laser supplies optical pulses to multiple sensor headslocated on several pieces of equipment.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 illustrates an optical particle monitoring system for fluids inaccordance with an embodiment of the invention. The system includes aplurality of optical sensors or “sensor heads” 10, 11, 12, eachconfigured to image the particles in a flowing fluid within a conduit14, 15, 16. The fluid can be, but is not limited to, oil or anotherlubricant. The sensors can be located at different points along a singlefluid flow, for example, at different locations along a conduit carryingcoolant for a single aircraft engine. Alternatively, the sensors can bepositioned to monitor different fluid flows in different components ordevices. The sensor heads 10, 11, 12, can be remotely located at adistance from the operator's workstation and computer. In this example,each of the sensor heads includes a light source 21 such as a laser. Thelight travels through viewing windows in the conduit and is received byan imaging system 24.

FIG. 2 illustrates a sensor head 10 suitable for use in an optical fluidparticle monitoring system for fluids. Referring first to sensor head10, the conduit 14 has an optically transparent portion 22 (a “viewingcell” or “windows”) that allows light to be transmitted through theconduit. On one side of the conduit, optical energy from a light source21 is directed through the window 22 into the flowing fluid 28. Theviewing cell 22 is a channel with two windows on opposite sides of thechannel that allow the light to pass through both windows, through thefluid, and out of the conduit to the imaging system 24.

The imaging system 24 is positioned on the other side of the viewingcell 22 to receive and image the portion of the optical energy that haspassed through the flowing fluid. As particles in the fluid pass throughthe viewing cell, the light source 21 illuminates the particles, and theresulting shadows are detected by the imaging system 24. In thisexample, the light source 21 is a laser located near the viewing cell,with the laser light carried to the viewing window by an optical fiber23.

In this example, the imaging system 24 can include an imaging lens 25and an electronic camera 26, positioned so the lens focuses the imageonto the camera's detector. The lens 25 can also enlarge the shadows toallow a desirable spatial resolution to be realized. The camera 26transmits the images to a computer processor 20 for image analysis foridentifying the number of particles, their size, and other informationabout the particles. Electronic image information is transmitted to thecomputer by cable 27, which can be either conductive or optical fiber,or by wireless signal transmission.

In an exemplary embodiment, the conduit is sized so that the particlesat any position in the cell will be in the near field of the imagingsystem (the range appropriate for Fresnel diffraction), with constraintsimposed by the particle size range, the wavelength of the light source,and the refractive index of the fluid.

The magnification of the imaging lens should be chosen to be appropriatefor each size range and can be different for each viewing cell, insystems with more than one viewing cell.

A coherent light source is preferred, because while an incoherent lightsource could be used, a coherent light source allows the viewing cellthickness to be much larger than that allowed by an incoherent lightsource for the same particle size range.

The coherent light source wavelength can be selected such that asufficient quantity of light is detectable, and enough light must alsobe absorbed or deflected by the particulate matter within the fluid suchthat there is a distinguishable difference between imaged portions ofthe fluid with particles and imaged portions of the fluid withoutparticles. The wavelength of the light source can be selected to lie ina reasonably transparent region of the fluid. For oils and lubricantscommonly encountered in mechanical machinery, such as aircraft or dieselengines, transmissions or gearboxes, a wavelength greater than 800 nmallows a sufficient quantity of light to be transmitted through the oil.A preferred wavelength range is between 800 and 1000 nm, but otherwavelengths at which the fluid is transparent can be chosen. Asingle-mode diode laser with a wavelength of 830 nm can be used toilluminate the oil used in aircraft engines.

For other fluids that are transparent in other wavelength ranges,different wavelengths for the illumination laser can be chosen,commensurate with the requirements of transparency of the fluid andavailability of suitable imaging detectors.

In operation, the light sources in the sensor head can be pulsed so a“stop action” image of fluid flowing within the chamber can be created.For each sensor head, with each pulse, a new image of fluid within thefluid chamber is created onto the optical detector. The pulse durationand the pulse repetition rate can be chosen with regard to the flowspeed of fluid and optical transmission of the fluid. The duration ofthe pulse should be short enough so that during the pulse the particlesdo not move by more than the desired spatial resolution. The use of ashort pulse duration with a two dimensional image allows reliablemeasures of particle size to be obtained without requiring knowledge orcontrol of the flow speed.

The laser source can be a pulsed laser, or a continuous wave laser incombination with a laser modulator to generate optical pulses ofcoherent light. It can also be suitable to use a continuous wave laserwithout a modulator and to gate the images within the imaging system, ifa camera with sufficiently fast gating is available.

In the example shown in FIG. 2, the laser 21 is located close to theview cell 22. In another example shown in FIG. 3, the laser 21 islocated remotely from the viewing cell and the optical fiber 23 carriesthe light to the viewing cell 22. The computer processor 20 is alsolocated remotely from the viewing window and conduit. The sensor head 30includes the end of the optical fiber 33, the viewing cell 22, andimaging system including a lens 25 and a camera 26. In FIG. 4, both thelaser 21 and the computer processor 20 are located near the viewingwindow and conduit, as part of the sensor head 40.

In each example, a small beam expander 29 can be positioned at the endof the optical fiber near the viewing window to expand the beam to asize that is commensurate with the required resolution and the size ofthe camera before the light enters the viewing window.

FIG. 5 illustrates a system that includes multiple sensor heads forevaluating the flow through a conduit, and for imaging particles over alarger range of sizes than could be imaged by a single sensor that usesnear field optical imaging techniques. The combination of cellthicknesses can be chosen to be appropriate for each particle sizerange, with some overlap of particle size range from one cell toanother, or the ranges can be disjoint, with no overlap between sizeranges. It is preferable that the cells are arranged in order such thatfluid flow encounters the largest viewing cell thickness first and thenencounters progressively smaller cells. Screen mesh or other filters canbe distributed between the cells to prevent larger particles fromclogging the smaller cells. The ability to simultaneously monitor afluid for particles of various sizes is very useful in monitoring thecondition of mechanical systems, in which early wear is associated withsmaller particles and more advanced wear is indicated by the presence oflarger particles.

In this example, a single laser illuminator 21, with multiple opticalfiber multiplexing, provides illumination to the sensor heads 52, 53,and 54. Optical fibers 61 are connected between the laser and the sensorheads and provide the light to the viewing cells in each sensor head.Alternatively, each sensor head can include a laser. The cameras in eachsensor head transmit the images to a computer processor 20 for imageprocessing and particle size analysis, although it is also suitable toinclude individual computer processors in each sensor head.

In this example, the thickness of the viewing cell in each sensor headis chosen to allow a particular range of particle sizes to be imaged,such that the objects throughout a cell are in the optical near field.The combination of cell thicknesses can be chosen to cover an overallrange of particle sizes that is larger than that provided by a singlecell. The sequence of cell thicknesses should be arranged such that thefluid flow encounters the largest cell first and then progressivelysmaller cells. Screen mesh filters can be distributed between the cellsto prevent larger particles from clogging smaller cells.

In FIG. 5, the first sensor head 52 is the first one encountered by thefluid in the conduit 51. A filter 57 can be positioned upstream of thefirst sensor head to exclude particles above a size threshold. Theconduit size can be reduced to ensure that the thickness t1 of theviewing window is the desired thickness to ensure particles of the sizedesired to be imaged are in the optical near field.

A second sensor head 53 is positioned downstream of the first sensorhead. The second sensor head has a viewing cell with thickness t2<t1,that is suitable for imaging a range of particles with smaller sizesthan the first sensor head, although there can be some overlap ofparticle ranges imaged by the first and second sensor heads. A pipereducing fitting 56 is shown in the conduit between the sensor heads 52and 53, to reduce the conduit diameter to the desired thickness t2 forthe viewing window in the second sensor head 53.

A filter 58 can be positioned in the conduit between the first andsecond sensor heads to exclude undesirably large particles from enteringthe viewing window (e.g., particles that are large enough to clog thedownstream viewing cells).

A third sensor head 54 is provided downstream of the sensor head 53. Thesensor head 54 is configured to image particles of even smaller sizethan those imaged by the viewing cells in sensor head 53. A pipereduction fitting 57 can be positioned between the upstream sensor head53 and the downstream sensor head 54 to reduce the conduit size from thelarger t2 thickness to a smaller t3 thickness to match the desiredviewing cell thickness. A filter 59 can be included with a mesh sizethat excludes particles that are large enough to clog the viewing cell.It is noted that the mesh sizes of the filters can also be selected tolimit the particle size to a maximum size that can be imaged by thedownstream viewing windows. The flow in the conduit 51 can be returnedto the main fluid flow 55 at a downstream location 60.

It is to be understood that the number of sensor heads can be greater orfewer than that shown in FIG. 5, depending on the complexity of thesystem to be monitored.

In an exemplary embodiment, the computer processor receives images fromthe sensor heads and performs image processing with a classifier module.The computer processor can determine, from the images, meaningfulinformation about the population of particles in the fluid flow at eachsensor head location. This information can include the number ofparticles in each particle size range and other quantities, such as butnot limited to, concentrations of air bubbles, water bubbles, nonmetallic particles, fibers, wear particles (cutting, sliding fatigue)and biological entities.

FIGS. 6A and 6B illustrate how possible combinations of cell thicknessescan be chosen to be appropriate for each particle size range. FIG. 6Ashows the result of selecting cell thicknesses to ensure some overlap ofparticle size range from one cell to another. FIG. 6B shows the resultof selecting cell thicknesses such that the particle size images aredisjoint, with no overlap between imaged particle size ranges.

In an exemplary embodiment, the image processing system embodied in thecomputer processor 20 instructions can select particular size rangeswhich are of greater interest for each sensor head. The particle sizeranges can be disjoint or can provide a chosen degree of overlap, whichcan be used to register the particle counting results from one cell tothe next. It is noted that if the overall particle size range hasdisjoint ranges in individual cells, gaps in the monitored particlesizes can occur.

FIG. 7 illustrates another example in which the individual sensorheads/viewing cells are connected separately to the main flow line andcombined with filters such that the larger particles do not flow througha cell chosen for monitoring smaller particles. In this example, a mainfluid flow 76 is tapped at two different locations to provide fluid toconduits 75 and 77. Each conduit includes a filter 73, 78 with a meshsized to exclude undesirably large particles from the viewing cells inthe sensor heads 74 and 79. As discussed above, the viewing window sizeand filters can be selected to have different sizes to provide a widerparticle size imaging capacity or can be sized identically, provideredundant capability. Although two sensor heads 74, 79 are shown in FIG.7, it is noted that more sensor heads can be included to provideadditional capability.

FIG. 8 shows an exemplary fluid monitoring system in which multiplesensor heads 63, 64 are arranged in parallel conduits having a singletap point 65 and a single return point 66 from the main fluid flow 62.In this example, the viewing cells in the sensor heads are sized toimage different particle size ranges. The parallel configuration of FIG.8 needs less total pressure drop than sensor heads arranged in series.In addition, in the parallel arrangement, if a filter becomes clogged,only the cell in that parallel arm is lost.

It is to be understood that the number of sensor heads can be greaterthan that the two sensor heads shown in each of FIGS. 7 and 8, dependingon the complexity of the system to be monitored and the type and varietyof sizes of the particles to be imaged.

It is to be understood that lasers and computer processors, plus anynecessary optical and electronic transmission links, are included in thesystems shown in FIG. 7 and FIG. 8. The FIG. 7 and FIG. 8 optical fluidmonitoring systems can be configured with a single laser coupled to allof the sensor heads or with a laser for each sensor head. Each of thesystems can be configured with a single computer processor coupled toall of the sensor heads or with a computer processor for each sensorhead.

FIG. 9 shows an exemplary fluid monitoring system in which a singlelaser 21 supplies optical pulses to multiple sensor heads located onseveral different fluid flow conduits. In this example, a portion of aclosed system fluid flow 80 flows into a conduit 81 for particle imagingand analysis. Sensor heads 82 and 82 image the fluid in the conduit inthe manner discussed above. The system can include filters and pipereduction fittings, or the sensor heads 82 and 83 can be redundantsystems, similar to the example shown in FIG. 5 and discussed above.

In each of the examples discussed above in which a single laser supplieslaser optical energy to a plurality of sensors, the multiplexing of thelaser signal for multiple sensors can be accomplished by division of theoptical energy from the laser 21 into optical fibers leading to eachviewing cell or sensor head. Alternatively, temporal multiplexing can beused, in which an entire pulse is directed to a single one of the cells,with different cells being illuminated in sequence using appropriateswitching electronics. For a multiple sensor-head system with temporalmultiplexing of return signals, the pulse repetition rate can be set toallow the signals from the sensor heads to be sequentially transmitted.

The systems described herein can advantageously provide informationabout a broader particle size range than previous near field opticalfluid particle monitoring systems. In addition, the systems can provideredundancy in case of equipment failure, particularly for equipment thatis difficult or dangerous to access.

Examples of fluids that are suitable for optical monitoring include, butare not limited to, lubricating and power transmission fluids, coolingliquids, water and water mixtures, fuels, and gases.

The systems described herein can also simultaneously monitor thepresence of particles in different fluid systems. As one example, avessel, a station, or a platform can include various pieces ofequipment, each of which can have one or more fluids requiringmonitoring (e.g., the fluids in the engines, transmission, and bearingson ships, aircraft, oil drilling platforms or other industrialinstallations such as power generating stations. A single laserilluminator and computer processor can be used to monitor multipleengines, transmission, bearings on ships, aircraft, oil drillingplatforms or other industrial installations such as power generatingstations.

In several of these examples, components of the system (e.g., laser,computer processor, user control station) can be located remotely fromthe conduit and the sensor heads. The distance between the laser and theviewing window in the sensor head, for example, can be severalkilometers or more, and is limited only by the transmission capabilityof the optical fiber between the components. Similarly, the computerprocessor can be several kilometers or more from the imaging system inthe sensor head.

In these examples, a notional sampling system, with simple pipe fittingsfrom the main flow passage, has been shown for illustrative purposes. Itis to be understood that the sampling systems described in U.S. Pat. No.6,049,381 to Reintjes et al., U.S. Pat. No. 6,049,381 to Reintjes etal., U.S. Pat. No. 7,921,739 to Fjerdingstad et al., and U.S. Pat. No.8,056,400 to Reintjes et al., are suitable for use in these systems.These documents are incorporated herein in their entireties.

The invention has been described with reference to certain preferredembodiments. It will be understood, however, that the invention is notlimited to the preferred embodiments discussed above, and thatmodification and variations are possible within the scope of theappended claims.

What is claimed as new and desired to be protected by Letters Patent ofthe United States is:
 1. An optical fluid monitoring system for imagingparticles in at least two conduits, each of the conduits arranged inparallel to receive a portion of a flowing fluid from a main flowpassageway, the system comprising: each of the conduits having anoptical sensor positioned to transmit laser optical energy into atransparent viewing window in the conduit in a direction across thedirection of flow, each sensor having an optical imaging system forreceiving the optical energy after it has passed through the fluid flowand for imaging particles in the fluid flow, wherein a first of theplurality of optical sensors is configured to image a range of largersize particles and a second of the plurality of optical sensors isconfigured to image a range of smaller size particles, wherein the firstsensor conduit has a conduit thickness that is larger than the secondsensor conduit, and wherein the conduit thickness at each of the opticalsensors is such that the particles in the size range to be imaged are inthe optical near field of the corresponding imaging system.
 2. Theoptical fluid monitoring system of claim 1, wherein the parallelconduits connect to a main flow passage at a same tap point and at asame return point.
 3. The optical fluid monitoring system of claim 1,further comprising: a filter in at least one of the conduits sized toexclude particles larger than a predetermined size from reaching theoptical sensor in that conduit.
 4. The optical fluid monitoring systemof claim 1, wherein each optical sensor includes a laser.
 5. The opticalfluid monitoring system of claim 4, wherein the lasers in each opticalsensor have different wavelengths.
 6. The optical fluid monitoringsystem of claim 4, wherein each optical sensor includes at least oneoptical fiber configured to transmit the optical energy of the laser tothe transparent viewing window.
 7. The optical fluid monitoring systemof claim 1, further comprising: a single laser operatively coupled toall of the optical sensors.
 8. The optical fluid monitoring system ofclaim 7, further comprising: a plurality of optical fibers transmittingthe optical energy output of the laser to the transparent viewingwindows.
 9. The optical fluid monitoring system of claim 1, wherein eachimaging system includes a camera and a lens, the lens disposed betweenthe camera and a viewing window in the conduit.
 10. The optical fluidmonitoring system of claim 1, further comprising: a single computerprocessor operatively connected to receive images from all of theimaging systems, the computer processor having programmed instructionsfor classifying particle shapes and sizes from the images received fromthe imaging system.
 11. The optical fluid monitoring system of claim 1,wherein each optical sensor includes a computer processor operativelyconnected to the imaging system in the optical sensor, each of thecomputer processor having programmed instructions for classifyingparticle shapes and sizes from the images received from the imagingsystem.
 12. The optical fluid monitoring system of claim 11, wherein thecomputer processor is located remote from the optical sensors.
 13. Theoptical fluid monitoring system of claim 1, further comprising: a singlelaser operatively coupled to all of the optical sensors; and a singlecomputer processor operatively connected to receive images from all ofthe imaging systems, the computer processor having programmedinstructions for classifying particle shapes and sizes from the imagesreceived from the imaging system.
 14. An optical fluid monitoring systemfor imaging particles in a flowing fluid, the system comprising: atleast two flow conduits positioned to receive a portion of a flowingfluid from a main flow passageway and to return the portion of theflowing fluid to the main passageway, each of the conduits having anoptical sensor positioned to transmit laser optical energy into atransparent viewing window in the conduit in a direction across thedirection of flow, each sensor having an optical imaging system forreceiving the optical energy after it has passed through the fluid flowand for imaging particles in the fluid flow, wherein a first of theplurality of optical sensors is configured to image a range of largersize particles and a second of the plurality of optical sensors isconfigured to image a range of smaller size particles, wherein the firstsensor conduit has a conduit thickness that is larger than the secondsensor conduit, and wherein the conduit thickness at each of the opticalsensors is such that the particles in the size range to be imaged are inthe optical near field of the corresponding imaging system, and whereina tap point and a return point for one of the conduits are bothpositioned downstream of a tap point and a return point for another oneof the conduits.
 15. The optical fluid monitoring system of claim 14,further comprising: a filter in at least one of the conduits sized toexclude particles larger than a predetermined size from reaching theoptical sensor in that conduit.
 16. The optical fluid monitoring systemof claim 14, wherein each optical sensor includes a laser.
 17. Theoptical fluid monitoring system of claim 16, wherein the lasers in eachoptical sensor have different wavelengths.
 18. The optical fluidmonitoring system of claim 14, wherein each optical sensor includes atleast one optical fiber configured to transmit the optical energy of thelaser to the transparent viewing window.
 19. The optical fluidmonitoring system of claim 14, further comprising: a single laseroperatively coupled to all of the optical sensors.
 20. The optical fluidmonitoring system of claim 19, further comprising: a plurality ofoptical fibers transmitting the optical energy output of the laser tothe transparent viewing windows.
 21. The optical fluid monitoring systemof claim 14, wherein each imaging system includes a camera and a lens,the lens disposed between the camera and a viewing window in theconduit.
 22. The optical fluid monitoring system of claim 14, furthercomprising: a single computer processor operatively connected to receiveimages from all of the imaging systems, the computer processor havingprogrammed instructions for classifying particle shapes and sizes fromthe images received from the imaging system.
 23. The optical fluidmonitoring system of claim 14, wherein each optical sensor includes acomputer processor operatively connected to the imaging system in theoptical sensor, each of the computer processor having programmedinstructions for classifying particle shapes and sizes from the imagesreceived from the imaging system.
 24. The optical fluid monitoringsystem of claim 23, wherein the computer processor is located remotefrom the optical sensors.
 25. The optical fluid monitoring system ofclaim 14, further comprising: a single laser operatively coupled to allof the optical sensors; and a single computer processor operativelyconnected to receive images from all of the imaging systems, thecomputer processor having programmed instructions for classifyingparticle shapes and sizes from the images received from the imagingsystem.